Ultra High Density Thin Film Transistor Substrate Having Low Line Resistance Structure and Method for Manufacturing the Same

ABSTRACT

A display device is described that has reduced resistance in one or more of the gate, common, data electrical lines that control the operation of the pixels of the display device. Reduced resistance is achieved by forming additional metal and/or metal-alloy layers on the gate, common, and/or data lines in such a manner so that the cross-sectional area of those lines is increased. As a consequence, each such line is formed so as to be thicker than could otherwise be achieving without causing defects in the rubbing process of an alignment layer. Additionally, no widening of these lines is needed, thus preserving the aspect ratio of the device. The gate insulating and semiconducting layers that in part make up the thin film transistors that help control the operation of the pixels of the device may also be designed to take into account the increased thickness of the lines.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No.15/801,120 filed on Nov. 1, 2017, which is a divisional of U.S.application Ser. No. 14/953,764 filed on Nov. 30, 2015, now U.S. Pat.No. 9,837,444, issued Dec. 5, 2017, which claims the benefit of KoreaPatent Application No. 10-2015-0100406 filed on Jul. 15, 2015, all ofwhich are incorporated herein by reference for all purposes as if fullyset forth herein.

BACKGROUND OF THE INVENTION Field of the Invention

The present disclosure relates to an ultra high density thin filmtransistor (or “TFT”) substrate having low resistance bus line structureand a method for manufacturing the same. Especially, the presentdisclosure relates to an ultra high density TFT substrate havingdouble-thick bus lines by forming the double layered gate line and dataline to have low resistance bus line structure and a method formanufacturing the same.

Discussion of the Related Art

Nowadays, various flat panel display devices are developed forovercoming many drawbacks of the cathode ray tube such as heavy weightand bulk volume. The flat panel display devices include the liquidcrystal display device (or LCD), the field emission display (or FED),the plasma display panel (or PDP) and the electroluminescence device (orED).

The flat panel display devices such as the liquid crystal display deviceor the organic light emitting diode display device have the substrateincluding a plurality of TFTs for using as the active display devices.FIG. 1 is a plane view illustrating the structure of the thin filmtransistor substrate used in the horizontal electric field type liquidcrystal display device according to the related art. FIGS. 2A to 2E arecross-sectional views illustrating the steps of manufacturing for thethin film transistor substrate of FIG. 1 by cutting along the line I-I′,according to the related art.

Referring to FIG. 1 and FIGS. 2A to 2E, the thin film transistorsubstrate of the LCD has a gate line GL and a data line DL crossing eachother with a gate insulating layer GI therebetween on a glass substrateSUB, and a thin film transistor TFT formed at each cross section of thegate line GL and the data line DL. The crossing structure of the gateline GL and the data line DL defines a pixel area. Further included area pixel electrode PXL and a common electrode COM for forming ahorizontal electric field therebetween in the pixel area, and a commonline CL connected to the common electrode COM on the substrate SUB. Thegate line GL supplies the gate signal to the gate electrode G of thethin film transistor TFT. The data line DL supplies the pixel signal tothe pixel electrode PXL via the drain electrode D of the thin filmtransistor TFT. The common line CL is formed in parallel with the gateline GL between the pixel areas and supplies a reference voltage fordriving the liquid crystal to the common electrode COM.

Responding to the gate signal supplied to the gate line GL, the thinfilm transistor TFT can charge the pixel signal from the data line DL topixel electrode PXL, and maintain the pixel signal on the pixelelectrode PXL. The pixel electrode PXL is formed within the pixel areaby being connected to the drain electrode D of the thin film transistorTFT. The common electrode COM is also formed within the pixel area bybeing connected to the common line CL. Especially, the pixel electrodePXL and the common electrode COM are disposed in parallel each other inthe pixel area. For example, the common electrode COM has a plurality ofvertical segments which are separately disposed with a predetermineddistance each other. The pixel electrode PXL has a plurality of verticalsegments in which each segments is disposed between the segments of thecommon electrode COM.

At one end portion of each gate line GL and each data line DL, a gatepad GP and a data pad DP are formed, respectively. The gate pad GP andthe data pad DP are connected to a gate pad terminal GPT and a data padterminal DPT through a gate pad contact hole GPH and a data pad contacthole DPH, respectively.

Referring to FIGS. 2A to 2E again, the method for manufacturing the thinfilm transistor substrate according to the related art will beexplained, hereinafter.

A gate metal is deposited on a substrate SUB. The gate elements areformed by patterning the gate metal using the first mask process. Asshown in FIG. 2A, the gate elements include a plurality of gate line GLrunning in horizontal direction, the gate electrode G branching from thegate line GL, and a gate pad GP formed at one end of the gate line GL.As the thin film transistor substrate is for the horizontal electricfield type, the common line CL disposed in parallel to the gate line GLis further included.

A gate insulating layer GI such as silicon nitride (SiNx) or siliconoxide (SiOx) is deposited on the whole surface of the substrate SUBhaving the gate elements. After that, a semiconductor material such asamorphous silicon and an impurity doped semiconductor material such asn+ doped silicon are sequentially deposited thereon. By patterning theimpurity doped semiconductor material and the semiconductor materialusing the second mask process, a semiconductor channel layer A and anohmic layer n are formed, as shown in FIG. 2B. The semiconductor channellayer A and the ohmic layer n are formed to be overlapped with the gateelectrode G having the gate insulating layer GI therebetween.

On the substrate SUB having the semiconductor channel layer A and theohmic layer n, a source-drain metal is deposited. By patterning thesource-drain metal using the third mask process, the source-drainelements are formed. As shown in FIG. 2C, the source-drain elementsinclude the data line DL running in vertical direction to cross with thegate line GL, a data pad DP formed at one end of the data line DL, thesource electrode S branching from the data line DL and overlapping withone side of the gate electrode G, and the drain electrode D facing withthe source electrode S and overlapping with the other side of the gateelectrode G. Especially, the source electrode S contacts one portion ofthe ohmic layer n to overlap with one side of the semiconductor channellayer A and the gate electrode G. The drain electrode D contacts antherportion of the ohmic layer n to overlap with the other side of thesemiconductor channel layer A and the gate electrode G. Further etchingthe ohmic layer n′ using the source-drain elements as a mask, theportions of the ohmic layer n′ exposed between the source electrode Sand the drain electrode D are removed so that the semiconductor channellayer A is exposed between the source electrode S and the drainelectrode D. Consequently, the thin film transistor TFT including thesource electrode S, the drain electrode D, the semiconductor channellayer A, and the gate electrode G is completed.

On the whole surface of the substrate SUB having the source-drainelements, a passivation layer PAS is formed by depositing an insulatingmaterial such as silicon nitride (SiNx) or silicon oxide (SiOx). Asshown in FIG. 2D, by patterning the passivation layer PAS using thefourth mask process, a data pad contact hole DPH exposing some portionsof the data pad DP and the drain contact hole DH exposing some portionsof the drain electrode D are formed. At the same time, by patterning thepassivation layer PAS and the gate insulating layer GI, a gate padcontact hole GPH exposing some portions of the gate pad GP and a commoncontact hole CH exposing some portions of the common line CL are formed.

On the passivation layer PAS having the contact holes GPH, DH, DPH andCH, a transparent conductive material such as ITO (Indium Tin Oxide) orIZO (Indium Zinc Oxide) is deposited. By patterning the transparentconductive material using the fifth mask process, the pixel electrodePXL, the common electrode COM, the gate pad terminal GPT and the datapad terminal DPT are formed, as shown in FIG. 2D. The pixel electrodePXL contacts the drain electrode D through the drain contact hole DH,and has a plurality of segments disposed in parallel within the pixelarea. The common electrode COM contacts the common line CL through thecommon contact hole CH, and has a plurality of segments disposed inparallel within the pixel area. The pixel electrode PXL and the commonelectrode COM are disposed in parallel each other with a predetermineddistance. The gate pad terminal GPT contacts the gate pad GP through thegate pad contact hole GPH, and the data pad terminal DPT contacts thedata pad DP through the data pad contact hole DPH.

The LCD according to the related art explained above has a problem tohave a large display area. Typically, as the area of the thin filmtransistor substrate is getting larger, the gate line and the data lineshould be getting longer and longer. As the bus lines are getting longerand longer, even though the resistivity of the bus line material is notchanged because it is the property of the material, the resistance ofthe bus line is getting larger and larger. The resistance of the busline is defined by the following Equation 1.

$\begin{matrix}{R = {\rho \frac{L}{S}}} & \left\lbrack {{Equation}\mspace{14mu} 1} \right\rbrack\end{matrix}$

Here, R is the resistance of the bus line, p is the resistivity of thebus line (such as the gate line GL (or gate bus line) and the data lineDL (or data bus line)) material, L is the length of the bus line, and Sis the cross-sectional area of the bus line.

That is, as the thin film transistor substrate is getting larger, thelength L will be longer so that the resistance is getting higher. As theresistance is getting higher, the signal passing through the bus linecan be delayed. As a result, the display device has the video qualityproblems. To solve these problems, the resistance of the bus line shouldbe reduced. To make the resistance of the bus line in lower state, thecross-sectional may be increased, or the bus line material can beselected as having a lower resistivity. To select a material having alower resistivity is very difficult because the material is limited.Furthermore, even it is possible, when the bus line is further gettinglonger and longer, the resistance will be higher again. Therefore, thebest solution to make the resistance of the bus line be in low is toenlarge the cross-sectional area of the bus line.

In order to increase the cross-sectional area of the bus line, there maybe two methods; one is to increase the width of the bus line, the otheris to increase the thickness of the bus line. For one example, byenlarging the width of the gate bus line and/or data bus line, it ispossible to prevent the resistance of the bus line from being increased.However, as the width of the bus lines defining the boundaries of thepixel area is also increased, the effective pixel area should bereduced. In that case, the aperture ratio of the display area is alsoreduced and it causes another reason of defected display quality. Foranother example, by enlarging the thickness of the bus lines, theetching tact time should be longer and longer when forming the bus linesand the space between the bus lines should be increased, so that it cancause the problem of lowered aperture ratio. Furthermore, as increasingthe thickness of the bus line, the step difference between the bus lineand other layer can be enlarged so that it causes the defects at rubbingprocess of the alignment layer.

Consequently, in the thin film transistor substrate for the largediagonal area flat panel display device, the bus line structure ensuringthe low resistance of the bus line is one of the important requirements.

SUMMARY OF THE INVENTION

In order to overcome the above mentioned drawbacks, the purpose of thepresent disclosure is to suggest an ultra high density thin filmtransistor substrate having a low resistance bus line structure forlarge area and ultra high density flat panel display device and a methodfor manufacturing the same. Another purpose of the present disclosure isto suggest an ultra high density thin film transistor substrate having alow resistance bus line structure in which the line resistance is notincreased even though the width of the line is being narrowed becausethat the thickness of the bus line is being thicker and a method formanufacturing the same. Still another purpose of the present disclosureis to suggest an ultra high density thin film transistor substratehaving a low resistance bus line structure in which the bus line has thedouble layered structure as having good uniformity of the bus linelayers and double the thickness. Yet another purpose of the presentdisclosure is to suggest an ultra high density thin film transistorsubstrate having a low resistance bus line structure and a method formanufacturing the same without increasing the complexity of themanufacturing steps and the tack time for the manufacturing, just byadding additional bus lines stacked on the bus line.

In one embodiment, a display device comprises a gate line, a commonline, and an additional data line (ADL) formed on a substrate. A gateinsulating layer is formed on a portion of the gate line and on aportion of the ADL. A semiconductor layer is formed on at least aportion of the gate insulating layer. A data line is formed on a portionof the ADL not covered by the gate insulating layer. An additional gateline (AGL) is formed on a portion of the gate line not covered by thegate insulating layer. An additional common line (ACL) formed on thecommon line. The display device includes a comprising a gate coupled tothe gate line, a source coupled to the data line, a drain, and a portionof the semiconductor layer at least partially located between the sourceand the drain.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are included to provide a furtherunderstanding of the invention and are incorporated in and constitute apart of this specification, illustrate embodiments of the invention andtogether with the description serve to explain the principles of theinvention.

In the drawings:

FIG. 1 is a plane view illustrating the structure of the thin filmtransistor substrate used in the horizontal electric field type liquidcrystal display device according to the related art.

FIGS. 2A to 2E are cross-sectional views illustrating the steps ofmanufacturing for the thin film transistor substrate of FIG. 1 bycutting along the line I-I′, according to the related art.

FIG. 3 is a plane view illustrating the structure of the ultra highdensity thin film transistor substrate used in the large area horizontalelectric field type liquid crystal display according to the presentdisclosure.

FIGS. 4A to 4E are cross-sectional views illustrating the steps ofmanufacturing for the ultra high density thin film transistor substrateof FIG. 1 by cutting along the line according to the present disclosure.

DETAILED DESCRIPTION OF THE ILLUSTRATED EMBODIMENTS

Referring to attached figures, we will explain preferred embodiments ofthe present disclosure. Like reference numerals designate like elementsthroughout the detailed description. However, the present disclosure isnot restricted by these embodiments but can be applied to variouschanges or modifications without changing the technical spirit. In thefollowing embodiments, the names of the elements are selected byconsidering the easiness for explanation so that they may be differentfrom actual names.

Hereinafter, referring to attached figures including FIG. 3 and FIGS. 4Ato 4E, we will explain preferred embodiments of the present disclosure.FIG. 3 is a plane view illustrating the structure of the ultra highdensity thin film transistor substrate used in the large area horizontalelectric field type liquid crystal display according to the presentdisclosure. FIGS. 4A to 4E are cross-sectional views illustrating thesteps of manufacturing for the ultra high density thin film transistorsubstrate of FIG. 1 by cutting along the line II-II′, according to thepresent disclosure.

Referring to FIG. 3 and FIGS. 4A to 4E, the thin film transistorsubstrate for an LCD comprises a gate line GL and a data line DL whichare crossing each other with a gate insulating layer therebetween on aglass substrate SUB, and a thin film transistor T formed at the crossingportion of the gate line GL and the data line DL. The crossing gate lineGL and the data line DL defines a pixel area. Further included are apixel electrode PXL and a common electrode COM for forming a horizontalelectric field therebetween in the pixel area, and a common line CLconnected to the common electrode COM on the substrate SUB. The gateline GL supplies the gate signal to the gate electrode G of the thinfilm transistor T. The data line DL supplies the pixel signal to thepixel electrode PXL via the drain electrode D of the thin filmtransistor T. The common line CL is formed between the pixel areas, isparallel with the gate line GL, and supplies a reference voltage signalfor driving the liquid crystal molecules to the common electrode COM.

Responding to the gate signal supplied to the gate line GL, the thinfilm transistor T can charge the pixel signal from the data line DL topixel electrode PXL, and maintain the pixel signal on the pixelelectrode PXL. The pixel electrode PXL is formed within the pixel areaby being connected to the drain electrode D of the thin film transistorT. The common electrode COM is also formed within the pixel area bybeing connected to the common line CL. Especially, the pixel electrodePXL and the common electrode COM are disposed in parallel each other inthe pixel area. For example, the common electrode COM has a plurality ofvertical segments (or vertical chevron segments) which are separatelydisposed with a predetermined distance each other. The pixel electrodePXL has a plurality of vertical segments (or vertical chevron segments)in which each segments is disposed between the segments of the commonelectrode COM.

At one end portion of each gate line GL and each data line DL, a gatepad GP and a data pad DP are formed, respectively. The gate pad GP andthe data pad DP are connected to a gate pad terminal GPT and a data padterminal DPT through a gate pad contact hole GPH and a data pad contacthole DPH, respectively.

In the present disclosure, in order to reduce the resistance of the gateline GL and the common line CL and to prevent the aperture ratio frombeing lowered, each line is formed to have double layered structure sothe thickness of the lines would be thicker than the related art.Particularly, the additional data line ADL, the additional gate lineAGL, and the additional common line ACL are included. The additionaldata line ADL is made of a gate metal material that is also used to formthe gate line GL and the common line CL. The additional gate line AGLand the additional common line ACL are made of a data metal materialthat is also used to form the data line DL.

According to the currently used technology, the maximum thickness of ametal layer by depositing the gate metal material and/or the data metalmaterial is about 4,000˜8,000 Å with ensuring the uniformity of themetal layer. Therefore, when the bus lines (gate line GL, common line CLor data line DL) are formed as the single layer structure, the maximumthickness of the bus line would be 8,000 Å.

In the present disclosure, by making the thickness of the bus lines bethicker rather than widening the width, we suggest a thin filmtransistor substrate having low line resistance with keeping theaperture ratio from being lowered. For example, the gate line GL and thecommon line CL are formed as having 8,000 Å thickness (the maximumthickness of single metal layer) with the gate metal material. Theadditional data line ADL is also formed with the gate metal materialwhere the data line DL will later be formed. As the data line DL crossesthe gate line GL, the additional data line ADL should be formed ashaving a multiple segments disconnected along to the data line DL anddisposed between the each gate lines GL running to horizontal directionor between the gate lines GL and the common lines CL. This prevents thesegments of the ADL from physically contacting or electrically couplingto the gate line GL or common line CL, particularly where the gate lineand data line cross each other.

After that, using the data metal material, the data line DL is formedwith 8,000 Å thickness, the maximum thickness of single metal layer.Here, the data line DL should be stacked on the additional data line ADLso that these two layers are directly physically connected in additionto being electrically coupled. The additional data line ADL having 8,000Å thickness and the data line DL having 8,000 Å thickness are stacked sothat the total thickness of the whole data bus line would be8,001-16,000 Å, in some cases twice the thickness of the data line DLalone. As the result, the line resistance of the data line DL can belowered relative to an implementation lacking the ADL. Depending uponthe embodiment, the ADL may be the same width as the DL, or slightlymore or less wide than the DL.

When the data line DL is formed using the data metal material, theadditional gate line AGL and the additional common line ACL are alsoformed with the data metal material. Both the AGL and ACL are formed tohave a 8,000 Å thickness, and they are formed where the gate line GL andthe common line CL are formed, respectively. The gate line GL having8,000 Å thickness and the additional gate line AGL having 8,000 Å arestacked so that these two layers are directly physically connected inaddition to being electrically coupled. Similarly, the common line CLhaving 8,000 Å thickness and the additional common line ACL having 8,000Å are stacked so that these two layers are directly physically connectedin addition to being electrically coupled. Consequently, the totalthickness of the whole gate bus line and the whole common bus line wouldbe 8,001-16,000 Å, in some cases twice the thickness of the gate line GLor common line CL alone. As the result, the line resistance of the gateline GL and the common line CL is lowered relatively to animplementation lacking the AGL and ACL. Further in an implementationincluding the ADL, AGL, and ACL, the width of the data line DL, gateline GL, and common line CL do not need to be widened to reduceresistance, and thus the aperture ratio is not reduced.

The gate line GL and the data line DL are crossing each other, and thecommon line CL and the data line DL are crossing each other. As the gateinsulating layer GI is inserted between the gate line GL and the dataline DL and between the common line CL and the data line DL at thecrossing point. Particularly, a thin film transistor T is disposed atthe crossing point between the gate line GL and the date line DL.Therefore, it is preferable that the gate insulating layer GI isdisposed as covering the area where the thin film transistor T isformed. Further, it is preferable that the gate insulating layer GI maycover some portions of the one end of the additional data line ADL(closer to the thin film transistor T). If the gate insulating layer GIdid not cover the end of the additional data line ADL, especiallyconsidering the margin for forming the gate insulating layer GI, thegate insulating layer GI would potentially be open at the end portionsof the gate line GL. However, by depositing the data line DL on the gateinsulating layer GI, the data line DL contacts the exposed portions ofthe gate line GL, thereby preventing accidental contact between the gateline GL and the data line DL.

It is preferable that the gate insulating layer GI may be disposed wherethe common line CL and the data line DL cross each other. Especially,the gate insulating layer GI may cover some portions of the other end ofthe additional data line ADL (far away from the thin film transistor T).

In the present disclosure, the gate insulating layer GI is disposed atthe necessary areas including the crossing area between the gate line GLand the data line DL and between the common line CL and the data line DLand the area where the thin film transistor T is disposed. Therefore,most of all portions of the gate line GL, the common line CL and theadditional data line ADL are exposed as not being covered by the gateinsulating layer GI. As the result, the bottom surface of the additionalgate line AGL stacking thereon contacts the upper surface of the gateline GL. Like that, the most of all surfaces of the additional commonline ACL contact the most of all surface of the common line CL. Further,the additional data line DL contact in surface with the surface of thedata line DL stacked on the additional data line ADL. The benefit offorming the gate insulating layers GI over portions of the substraterather than over the entirety of the substrate (as is illustrated inFIGS. 1 and 2) is that it allows the later formed AGL, DL, and ACL(formed after the gate insulating layer GI) to physically andelectrically contact the earlier formed GL, ADL, and CL, respectively(formed before the gate insulating layer GI). Forming the gateinsulating layer GI in this manner also has the effect of ensuring thata portion of the data line DL that serves as the source of the thin filmtransistor is at an appropriate height in relation to the channel of thetransistor (formed by a portion of the semiconductor layer SE) and inrelation to the drain of the transistor.

The gate line GL and the data line DL may themselves have a multiplelayer structure in which multiple metal layers or multiple alloy layersare stacked each other. For the large area display, the line resistancemay be higher than that of the small area display. So, it is preferablethat the bus line (e.g., the gate line bus, data line bus), andtherefore the gate metal material and data metal material, includes alow resistance metal material such as the copper (Cu) or aluminum (Al).For example, either bus line may include a first metal layer includingmolybdenum-titanium alloy and the second metal layer having the copperstacked on the first metal layer. As the additional data line ADL andthe additional gate line AGL are formed at the same layer and with thesame metal material/s as the gate line GL and the data line DL,respectively, it is therefore also the case that the additional dataline ADL and the additional gate line AGL may also have a stackedstructure including multiple metal layers or multiple alloy layers.Depending upon the embodiment, the AGL and the ACL may be the same widthas the GL and the CL, respectively, or they may be slightly more or lesswide than the GL and the CL, respectively.

As the thin film transistor T is disposed where the gate line GL and thedate line DL are crossing each other, it is preferable that thesemiconductor layer SE is disposed and stacked on the gate insulatinglayer GI as having the same shape with the gate insulating layer GI. Forthis structure, we will explain in the method for manufacturing the thinfilm transistor substrate in detail.

Hereinafter, referring to FIGS. 4A to 4E, we will explain about a methodfor manufacturing the ultra high density thin film transistor substratehaving the low resistance bus line structure according to the presentdisclosure. FIGS. 4A to 4E are cross-sectional views illustrating thesteps of manufacturing for the ultra high density thin film transistorsubstrate of FIG. 1 by cutting along the line according to the presentdisclosure.

As shown in FIG. 4A, a gate metal material is deposited with thicknessof 4,000˜8,000 Å on the transparent substrate SUB. Patterning the gatemetal material using the first mask process, the gate elements areformed. The gate elements include a gate line GL, a common line CL, agate pad GP, a common pad CP, a gate electrode G and an additional dataline ADL. The gate line GL and the common line CL may run to thehorizontal direction on the substrate SUB. The gate pad GP is formed atone end of the gate line GL. The common pad CP is formed at one end ofthe common line CL. The gate electrode G may be branched from the gateline GL where the gate line GL and the data line are crossing eachother. The additional data line ADL is disposed between the gate line GLand the common line CL. The additional data line ADL has a segment shapebeing apart from the gate line GL and the common line CL and running tovertical direction on the substrate. The additional data line ADL isformed and is physically connected with the data line DL such that it iselectrically and physically isolated from the gate line GL and thecommon line CL.

As shown in FIG. 4B, on the substrate having the gate elements, a gateinsulating material and a semiconductor material are sequentiallydeposited. By patterning the gate insulating material and thesemiconductor material at the same time using the second mask process, agate insulating layer GI and a semiconductor layer SE are formed. Thegate insulating layer GI and the semiconductor layer SE are disposedwhere a thin film transistor T is formed and where the data line DLcrosses with the gate line GL or the common line CL. For example, theymay cover the gate electrode G thoroughly and some portions of both endsof the additional data line ADL. However, this overlap by the gateinsulating layer GI and the semiconductor layer SE covers (is stacked ontop of) less than a majority of the gate line GL, the common line CL andthe additional data line ADL.

In a more specific embodiment (not shown), the semiconductor layer SEmay be disposed only where the thin film transistor T is formed. Forexample, at the crossing point where the common line CL and the dataline DL are crossing each other, only the gate insulating layer GI isdisposed without the semiconductor layer SE. At the crossing point wherethe gate line GL and the data line DL are crossing each other, the gateinsulating layer GI and the semiconductor layer SE are disposed as beingstacked. To do so, the second mask process may use a half-tone mask or aslit mask.

Returning to the example embodiment illustrated in FIGS. 4A-4E, the gateinsulating layer GI and the semiconductor layer SE are disposed at theboth areas where the common line CL and the data line DL are crossingeach other and where the gate line GL and the data line DL are crossingeach other. In this case, it is preferable that the semiconductor layerSE has the smaller size than that of the gate insulating layer GI. To doso, when selecting the etching material in the second mask process, itis preferable to consider the etching material having the etching ratioto the semiconductor material larger than the etching ratio to the gateinsulating material.

As shown in FIG. 4C, on the substrate SUB having the gate insulatinglayer GI and the semiconductor layer SE patterned in the island shape, adata metal material is deposited with the thickness of 4,000˜8,000 Å.Patterning the data metal material using the third mask process, thedata elements are formed. The data elements include a data line DL, adata pad DP, a source electrode S, a drain electrode D, an additionalgate line AGL and an additional common line ACL. The data line DL runsto the vertical direction on the substrate SUB and is in surface contactwith the additional data line ADL which the multiple segments aredisposed in a line. Therefore, the data line DL is crossing with thegate line GL and the common line CL on the gate insulating layer GI andthe semiconductor layer SE covering some of the gate line GL and thecommon line CL. The data pad DP is formed at one end of the data lineDL. The source electrode S is branched from the data line DL andcontacting on the one side of the semiconductor layer SE. The drainelectrode D is contacting on the other side of the semiconductor layerSe, and apart from the source electrode S with a predetermined distance.The portions of the semiconductor layer SE between the source electrodeS and the drain electrode D is defined as the channel area A. So, thethin film transistor T including the gate electrode G, the semiconductorchannel area A, the source electrode S and the drain electrode D iscompleted. The additional gate line AGL is in surface contact with thegate line GL which is not covered by the gate insulating layer GI andthe semiconductor layer SE. Likewise, the additional common line ACL isin surface contact with the common line CL which is not covered by thegate insulating layer GI and the semiconductor layer SE.

As shown in FIG. 4D, depositing an insulating material such as siliconnitride (SiNx) or silicon oxide (SiOx) on the whole surface of thesubstrate SUB having the data elements, a passivation layer PAS isdeposited. Patterning the passivation layer PAS using the fourth maskprocess, contact holes are formed. The contact holes include a draincontact hole DH, a gate pad contact hole GPH, a common line contact holeCH, a data pad contact hole DPH. The drain contact hole DH exposes someportions of the drain electrode D. The gate pad contact hole GPH exposessome portions of the gate pad GP. The common line contact hole CHexposes some portions of the common line CL. The data pad contact holeDPH exposes some portions of the data pad DP.

As shown in FIG. 4E, on the passivation layer PAS having the contactholes, an electrode material is deposited. The electrode material mayinclude a transparent conductive material such as indium-tin-oxide (ITO)and indium-zinc-oxide (IZO). In some cases, the electrode material mayinclude an opaque conductive material such as molybdenum (Mo), titanium(Ti) or molybdenum-titanium ally (MoTi). Patterning the electrodematerial using the fifth mask process, a pixel electrode PXL, a commonelectrode COM, a gate pad terminal GPT, and a data pad terminal DPT areformed. The pixel electrode PXL connects to the drain electrode Dthrough the drain contact hole DH, and has a plurality of segmentsarrayed in parallel in one pixel area. The common electrode COM connectsto the common line CL through the common line contact hole CH, and has aplurality of segments arrayed in parallel with each segment of the pixelelectrode PXL. The gate pad terminal GPT connects to the gate terminalGP through the gate pad contact hole GPH. The data pad terminal DPTconnects to the data terminal DP through the data pad contact hole DPH.

In the present disclosure, the gate line GL is in surface contact withthe additional gate line AGL in which the top surface of the gate lineGL is in surface contact with the bottom surface of the additional gateline AGL. Particularly, a majority of the bottom surface of theadditional gate line AGL is in physical contact with the majority of thetop surface of the gate line GL. A series of additional gate lines AGLsare disposed along the length of the gate line GL. As an added benefit,as the additional gate line AGL can be formed when the data line DL isformed, it can be formed without any additional mask process.

Likewise, the data line DL is in surface contact with the additionaldata line ADL in which the bottom surface of the data line DL is insurface contact with the top surface of the additional data line ADL.Particularly, a majority of the top surface of the additional data lineADL is in physical contact with a majority of the bottom surface of thedata line DL. A series of additional data lines ADLs are disposed alongthe length of the data line DL. As an additional benefit, as theadditional data line ADL can be formed when the gate line GL is formed,it can be formed without any additional mask process.

Consequently, with the same width of the bus line, the line resistancecan be reduced by thickening the thickness of the bus line. For example,in the currently used TV panel over 45 inch diagonal length, the pixeldensity is about 40 PPI at maximum, the width of the gate line GL is 60μm and the width of the data line DL is 10 μm. In order to design andmanufacture an ultra-high density flat panel display having over 90 PPIin the TV panel over 45 inch diagonal length, the width of the gate lineGL would be 40 μm and the width of the data line would be 5 μm. When thewidths of the lines are narrowed like that, the line resistance would beremarkably increased so that it is hard to represent good video data.According to the present disclosure, even though the widths of the linesare narrowed, the thicknesses of the lines would be increased.Therefore, the line resistance may not be increased and better qualityof the video data can be ensured.

While the embodiment of the present invention has been described indetail with reference to the drawings, it will be understood by thoseskilled in the art that the invention can be implemented in otherspecific forms without changing the technical spirit or essentialfeatures of the invention. Therefore, it should be noted that theforgoing embodiments are merely illustrative in all aspects and are notto be construed as limiting the invention. The scope of the invention isdefined by the appended claims rather than the detailed description ofthe invention. All changes or modifications or their equivalents madewithin the meanings and scope of the claims should be construed asfalling within the scope of the invention.

What is claimed is:
 1. A display device comprising: a substrate having afirst area, and a second area outside of the first area, the second areaincluding a link area and a pad area outside of the link area; gatelines and data lines crossing each other, and thin film transistorsadjacent to crossings of the gate lines and the data lines in the firstarea, each of the thin film transistors including a source electrode, asemiconductor channel layer and a drain electrode; a first line extendedfrom each of the gate lines and an additional gate line formed of a samematerial as the data line in the link area, the additional gate linebeing contacted with the first line in the link area; and a gate padextended from each of the first lines and a gate pad terminal on thegate pad, in the pad area.
 2. The display device of claim 1, furthercomprising; an additional data line positioned on a same layer as thegate line to be separated from the gate line; a data pad extended fromthe additional data line, in the pad area; and a data pad terminal onthe data pad, in the pad area.
 3. The display device of claim 2, whereinthe gate pad terminal and the data pad terminal are formed of a samematerial.
 4. The display device of claim 1, further comprising asemiconductor layer on a gate insulating layer covering the first linein the pad area, wherein the additional gate line is connected to asurface of the first line and a side of at least one of the first lineand the semiconductor layer.
 5. The display device of claim 4, furthercomprising a common line, and an additional data line positioned on asame layer as the gate line to be separated from the gate line.
 6. Thedisplay device of claim 5, further comprising an additional common lineon the common line in the first area, wherein the data line, theadditional gate line, and the additional common line are formed of asame data material.
 7. The display device of claim 6, wherein at a pointwhere the common line and the data line cross each other, the gateinsulating layer is formed and the semiconductor layer is not formed. 8.The display device of claim 6, wherein the gate insulating layer and thesemiconductor layer are both formed at a point where the gate line andthe data line cross each other.
 9. The display device of claim 6,wherein the gate insulating layer is formed on a portion of theadditional data line, the additional common line is in contact with aportion of the common line not covered by the gate insulating layer, andthe data line is formed on a portion of the gate insulating layer formedon a portion of the additional data line.
 10. The display device ofclaim 1, wherein the gate line and the data line are formed of a stackedstructure comprising multiple metal layers, multiple alloy layers, ormultiple layers including at least one metal layer and at least onealloy layer.
 11. The display device of claim 10, wherein the stackedstructure comprises a layer of molybdenum-titanium alloy and a layer ofcopper or aluminum.
 12. The display device of claim 2, wherein theadditional data line is formed in a plurality of segments along the dataline, and wherein one of the segments is disposed between the gate lineand an adjacent gate line or between the gate line and a common line.13. The display device of claim 1, wherein a majority of a bottomsurface of the additional gate line is in physical contact with amajority of a top surface of the gate line.
 14. The display device ofclaim 2, wherein a majority of a bottom surface of the additional dataline is in physical contact with a majority of a top surface of the dataline.
 15. The display device of claim 2, wherein the gate insulatinglayer covers less than a majority of the gate line, and the additionaldata line.
 16. The display device of claim 1, wherein the additionalgate line is positioned on the gate line not covered by a gateinsulating layer covering the gate line, the data line and the gateelectrode in the first area.